Category Archives: probiotics

Bacillus as probiotics

12th August 2017

The probiotics

Probiotics are living microorganisms that, when ingested in adequate amounts, can have a positive effect on the health of guests (FAO / WHO 2006; World Gastroenterology Organization 2011, Fontana et al., 2013). Guests can be humans but also other animals. Lactic acid bacteria, especially the genus Lactobacillus and Bifidobacterium, both considered as GRAS (Generally recognized as safe), are the microbes most commonly used as probiotics, but other bacteria and some yeasts can also be useful. Apart from being able to be administered as medications, probiotics are commonly consumed for millennia as part of fermented foods, such as yoghurt and other dairy products (see my article “European cheese from 7400 years ago..” “December 26th, 2012). As medications, probiotics are generally sold without prescription, over-the-counter (OTC) in pharmacies.

I have already commented on the other posts of this blog the relevance of probiotics (“A new probiotic modulates microbiota against hepatocellular carcinoma” August 24th, 2016), as well as the microbiota that coexists with our body (“Bacteria in the gut controlling what we eat” October 12th, 2014; “The good bacteria of breast milk” February 3rd, 2013) and other animals (“Human skin microbiota … and our dog” December 25th, 2015; “The herbivore giant panda …. and its carnivore microbiota” September 30th, 2015).

Besides lactic acid bacteria and bifidobacteria, other microorganisms that are also used to a certain extent as probiotics are the yeast Saccharomyces cerevisiae, some strains of Escherichia coli, and some Bacillus, as we will see. Some clostridia are also used, related to what I commented in a previous post of this blog by March 21st, 2015 (“We have good clostridia in the gut ...”).

 

The Bacillus

In fact, Bacillus and clostridia have in common the ability to form endospores. And both groups are gram-positive bacteria, within the taxonomic phylum Firmicutes (Figure 1), which also includes lactic acid bacteria. However, bacilli (Bacillus and similar ones, but also Staphylococcus and Listeria) are more evolutionarily closer to lactobacillalles (lactic acid bacteria) than to clostridia ones. The main physiological difference between Clostridium and Bacillus is that the first are strict anaerobes while Bacillus are aerobic or facultative anaerobic.

Fig 1 tree gram+ eng

Figure 1. Phylogenetic tree diagram of Gram-positive bacteria (Firmicutes and Actinobacteria). Own elaboration.

 

Bacterial endospores (Figure 2) are the most resistant biological structures, as they survive extreme harsh environments, such as UV and gamma radiation, dryness, lysozyme, high temperatures (they are the reference for thermal sterilization calculations), lack of nutrients and chemical disinfectants. They are found in the soil and in the water, where they can survive for very long periods of time.

Fig 2 bacillus Simon Cutting

Figure 2. Endospores (white parts) of Bacillus subtilis in formation (Image of Simon Cutting).

 

Bacillus in fermented foods, especially Asian

Several Bacillus are classically involved in food fermentation processes, especially due to their protease production capacity. During fermentation, this contributes to nutritional enrichment with amino acids resulting from enzymatic proteolysis.

Some of these foods are fermented rice flour noodles, typical of Thailand and Burma (nowadays officially Myanmar). It has been seen that a variety of microorganisms (lactic acid bacteria, yeasts and other fungi) are involved in this fermentation, but also aerobic bacteria such as B. subtilis. It has been found that their proteolytic activity digests and eliminates protein rice substrates that are allergenic, such as azocasein, and therefore they have a beneficial activity for the health of consumers (Phromraksa et al. 2009).

However, the best-known fermented foods with Bacillus are the alkaline fermented soybeans. As you know, soy (Glycine max) or soya beans are one of the most historically consumed nourishing vegetables, especially in Asian countries. From they are obtained “soy milk”, soybean meal, soybean oil, soybean concentrate, soy yogurt, tofu (soaked milk), and fermented products such as soy sauce, tempeh, miso and other ones. Most of them are made with the mushroom Rhizopus, whose growth is favoured by acidification or by direct inoculation of this fungus. On the other hand, if soy beans are left to ferment only with water, the predominant natural microbes fermenting soy are Bacillus, and in this way, among other things, the Korean “chongkukjang” is obtained, “Kinema” in India, the “thua nao” in northern Taiwan, the Chinese “douchi”, the “chine pepoke” from Burma, and the best known, the Japanese “natto” (Figure 3). Spontaneous fermentation with Bacillus gives ammonium as a by-product, and therefore is alkaline, which gives a smell not very good to many of these products. Nevertheless, natto is made with a selected strain of B. subtilis that gives a smoother and more pleasant smell (Chukeatirote 2015).

These foods are good from the nutritional point of view as they contain proteins, fibre, vitamins, and they are of vegetable or microbial origin. In addition, the advertising of the commercial natto emphasizes, besides being handmade and sold fresh (not frozen), its probiotic qualities, saying that B. subtilis (Figure 4) promotes health in gastrointestinal, immunologic, cardiovascular and osseous systems (www.nyrture.com). They say the taste and texture of natto are exquisite. It is eaten with rice or other ingredients and sauces, and also in the maki sushi. We must try it !

OLYMPUS DIGITAL CAMERA

Figure 3. “Natto”, soybeans fermented with B. subtilis, in a typical Japanese breakfast with rice (Pinterest.com).

Fig 4 Bs nyrture-com micrograf electro colorejada

Figure 4. Coloured electronic micrograph of Bacillus subtilis (Nyrture.com).

 

Bacillus as probiotics

The endospores are the main advantage of Bacillus being used as probiotics, thanks to their thermal stability and to survive in the gastric conditions (Cutting 2011). Although Clostridium has also this advantage, its strict anaerobic condition makes its manipulation more complex, and moreover, for the “bad reputation” of this genus due to some well-known toxic species.

Unlike other probiotics such as Lactobacillus or Bifidobacterium, Bacillus endospores can be stored indefinitely without water. The commercial products are administered in doses of 10^9 spores per gram or per ml.

There are more and more commercial products of probiotics containing Bacillus, both for human consumption (Table 1) and for veterinary use (Table 2). In addition, there are also five specific products for aquaculture with several Bacillus, and also shrimp farms are often using products of human consumption (Cutting 2011).

For use in aquaculture, probiotic products of mixtures of Bacillus (B. thuringiensis, B. megaterium, B. polymixa, B. licheniformis and B. subtilis) have been obtained by isolating them from the bowel of the prawn Penaeus monodon infected with vibriosis. They have been selected based on nutrient biodegradation and the inhibitory capacity against the pathogen Vibrio harveyi (Vaseeharan & Ramasamy 2003). They are prepared freeze-dried or microencapsulated in sodium alginate, and it has been shown to significantly improve the growth and survival of shrimp (Nimrat et al., 2012).

As we see for human consumption products, almost half of the brands (10 of 25) are made in Vietnam. The use of probiotic Bacillus in this country is more developed than in any other, but the reasons are not clear. Curiously, as in other countries in Southeast Asia, there is no concept of dietary supplements and probiotics such as Bacillus are only sold as medications approved by the Ministry of Health. They are prescribed for rotavirus infection (childhood diarrhoea) or immune stimulation against poisoning, or are very commonly used as a therapy against enteric infections. However, it is not clear that clinical trials have been carried out, and they are easy-to-buy products (Cutting 2011).

 

Table 1. Commercial products of probiotics with Bacillus, for human consumption (modified from Cutting 2011).

Product Country where it is made Species of Bacillus
Bactisubtil ® France B. cereus
Bibactyl ® Vietnam B. subtilis
Bidisubtilis ® Vietnam B. cereus
Bio-Acimin ® Vietnam B. cereus and 2 other
Biobaby ® Vietnam B. subtilis and 2 other
Bio-Kult ® United Kingdom B. subtilis and 13 other
Biosporin ® Ukraine B. subtilis + B. licheniformis
Biosubtyl ® Vietnam B. cereus
Biosubtyl DL ® Vietnam B. subtilis and 1 other
Biosubtyl I and II ® Vietnam B. pumilus
Biovicerin ® Brazil B. cereus
Bispan ® South Korea B. polyfermenticus
Domuvar ® Italy B. clausii
Enterogermina ® Italy B. clausii
Flora-Balance ® United States B. laterosporus *
Ildong Biovita ® Vietnam B. subtilis and 2 other
Lactipan Plus ® Italy B. subtilis *
Lactospore ® United States B. coagulans *
Medilac-Vita ® China B. subtilis
Nature’s First Food ® United States 42 strains, including 4 B.
Neolactoflorene ® Italy B. coagulans * and 2 other
Pastylbio ® Vietnam B. subtilis
Primal Defense ® United States B. subtilis
Subtyl ® Vietnam B. cereus
Sustenex ® United States B. coagulans

* Some labelled as Lactobacillus or other bacteria are really Bacillus

 

Table 2. Commercial products of probiotics with Bacillus, for veterinary use (modified from Cutting 2011).

Product Animal Country where it is made Species of Bacillus
AlCare ® Swine Australia B. licheniformis
BioGrow ® Poultry, calves and swine United Kingdom B. licheniformis and B. subtilis
BioPlus 2B ® Piglets, chickens, turkeys Denmark B. licheniformis and B. subtilis
Esporafeed Plus ® Swine Spain B. cereus
Lactopure ® Poultry, calves and swine India B. coagulans *
Neoferm BS 10 ® Poultry, calves and swine France B. clausii
Toyocerin ® Poultry, calves, rabbits and swine Japan B. cereus

 

The Bacillus species that we see in these Tables are those that really are found, once the identification is made, since many of these products are poorly labelled as Bacillus subtilis or even as Lactobacillus (Green et al. 1999; Hoa et al. 2000). These labelling errors can be troubling for the consumer, and especially for security issues, since some of the strains found are Bacillus cereus, which has been shown to be related with gastrointestinal infections, since some of them produce enterotoxins (Granum & Lund 1997; Hong et al. 2005)

The probiotic Bacillus have been isolated from various origins. For example, some B. subtilis have been isolated from the aforementioned Korean chongkukjang, which have good characteristics of resistance to the gastrointestinal tract (GI) conditions and they have antimicrobial activity against Listeria, Staphylococcus, Escherichia and even against B. cereus (Lee et al. 2017).

One of the more known probiotics pharmaceuticals is Enterogermina ® (Figure 5), with B. subtilis spores, which is recommended for the treatment of intestinal disorders associated with microbial alterations (Mazza 1994).

Figuresv1 copy.ppt

Figure 5. Enterogermina ® with spores of Bacillus subtilis (Cutting 2011)

 

Bacillus in the gastrointestinal tract: can they survive there ?

It has been discussed whether administered spores can germinate in the GI tract. Working with mice, Casula & Cutting (2002) have used modified B. subtilis, with a chimeric gene ftsH-lacZ, which is expressed only in vegetative cells, which can be detected by RT-PCR up to only 100 bacteria. In this way they have seen that the spores germinate in significant numbers in the jejunum and in the ileum. That is, spores could colonize the small intestine, albeit temporarily.

Similarly, Duc et al. (2004) have concluded that B. subtilis spores can germinate in the gut because after the oral treatment of mice, in the faeces are excreted more spores that the swallowed ones, a sign that they have been able to proliferate. They have also detected, through RT-PCR, mRNA of vegetative bacilli after spore administration, and in addition, it has been observed that the mouse generates an IgG response against bacterial vegetative cells. That is, spores would not be only temporary stagers, but they would germinate into vegetative cells, which would have an active interaction with the host cells or the microbiota, increasing the probiotic effect.

With all this, perhaps it would be necessary to consider many Bacillus as not allochthonous of the GI tract, but as bacteria with a bimodal growth and sporulation life cycle, both in the environment and in the GI tract of many animals (Hong et al. 2005).

Regarding the normal presence of Bacillus in the intestine, when the different microorganisms inhabiting the human GI tract are studied for metagenomic DNA analysis of the microbiota, the genus Bacillus does not appear (Xiao et al., 2015). As we can see (Figure 6), the most common are Bacteroides and Clostridium, followed by various enterobacteria and others, including bifidobacteria.

Fig 6 Xiao nbt.3353-F2

Figure 6. The 20 bacterial genera more abundant in the mice (left) and human (right) GI tract (Xiao et al. 2015).

 

In spite of this, several species of Bacillus have been isolated from the GI tract of chickens, treating faecal samples with heat and ethanol to select only the spores, followed by aerobic incubation (Barbosa et al. 2005). More specifically, the presence of B. subtilis in the human microbiota has been confirmed by selective isolation from biopsies of ileum and also from faecal samples (Hong et al. 2009). These strains of B. subtilis exhibited great diversity and had the ability to form biofilms, to sporulate in anaerobiosis and to secrete antimicrobials, thereby confirming the adaptation of these bacteria to the intestine. In this way, these bacteria can be considered intestinal commensals, and not only soil bacteria.

 

Security of Bacillus as probiotics

The oral consumption of important amounts of viable microorganisms that are not very usual in the GI treatment raises additional doubts about safety. Even more in the use of species that do not have a history of safe use in foods, as is the case of sporulated bacteria. Even normal bowel residents may sometimes act as opportunistic pathogens (Sanders et al. 2003).

With the exception of B. anthracis and B. cereus, the various species of Bacillus are generally not considered pathogenic. Of course, Bacillus spores are commonly consumed inadvertently with foods and in some fermented ones. Although Bacillus are recognized as GRAS for the production of enzymes, so far the FDA has not guaranteed the status of GRAS for any sporulated bacteria with application as a probiotic, neither Bacillus nor Clostridium. While Lactobacillus and Bifidobacterium have been the subject of numerous and rigorous tests of chronic and acute non-toxicity, and a lot of experts have reviewed data and have concluded that they are safe as probiotics, there is no toxicity data published on Bacillus in relation to their use as probiotics. When reviewing articles on Medline with the term “probiotic” and limited to clinical studies, 123 references appear, but Bacillus does not appear in any of them (Sanders et al. 2003).

Instead, there are some clinical studies where Bacillus strains have been detected as toxigenic. All this explains that some probiotic Bacillus producers refer to them with the misleading name of Lactobacillus sporogenes, a non-existent species, as can be seen from NCBI (https://www.ncbi.nlm.nih.gov/taxonomy/?term = Lactobacillus + sporogenes).

Finally, we should remember the joint report on probiotics of FAO (United Nations Food and Agriculture Organization) and WHO (World Health Organization) (FAO / WHO 2006), which suggests a set of Guidelines for a product to be used as a probiotic, alone or in the form of a new food supplement. These recommendations are:

  1. The microorganism should be well characterized at the species level, using phenotypic and genotypic methods (e.g. 16S rRNA).
  2. The strain in question should be deposited in an internationally recognized culture collection.
  3. To evaluate the strain in vitro to determine the absence of virulence factors: it should not be cytotoxic neither invades epithelial cells, and not produce enterotoxins or haemolysins or lecithinases.
  4. Determination of its antimicrobial activity, and the resistance profile, including the absence of resistance genes and the inability to transfer resistance factors.
  5. Preclinical evaluation of its safety in animal models.
  6. Confirmation in animals demonstrating its effectiveness.
  7. Human evaluation (Phase I) of its safety.
  8. Human evaluation (Phase II) of its effectiveness (if it does the expected effect) and efficiency (with minimal resources and minimum time).
  9. Correct labelling of the product, including genus and species, precise dosage and conservation conditions.

FAO WHO

Conclusions

The use of Bacillus as probiotics, especially in the form of dietary supplements, is increasing very rapidly. More and more scientific studies show their benefits, such as immune stimulation, antimicrobial activities and exclusive competition. Their main advantage is that they can be produced easily and that the final product, the spores, is very stable, which can easily be incorporated into daily food. In addition, there are studies that suggest that these bacteria may multiply in GI treatment and may be considered as temporary stagers (Cutting 2011).

On the other hand, it is necessary to ask for greater rigor in the selection and control of the Bacillus used, since some, if not well identified, could be cause of intestinal disorders. In any case, since the number of products sold as probiotics that contain the sporulated Bacillus is increasing a lot, one must not assume that all are safe and they must be evaluated on a case-by-case basis (Hong et al. 2005).

 

Bibliography

Barbosa TM, Serra CR, La Ragione RM, Woodward MJ, Henriques AO (2005) Screening for Bacillus isolates in the broiler gastrointestinal tract. Appl Environ Microbiol 71, 968-978.

Casula G, Cutting SM (2002) Bacillus probiotics: Spore germination in the gastrointestinal tract. Appl Environ Microbiol 68, 2344-2352.

Chukeatirote E (2015) Thua nao: Thai fermented soybean. J Ethnic Foods 2, 115-118.

Cutting SM (2011) Bacillus probiotics. Food Microbiol 28, 214-220.

Duc LH, Hong HA, Barbosa TM, Henriques AO, Cutting SM (2004) Characterization of Bacillus probiotics available for human use. Appl Environ Microbiol 70, 2161-2171.

FAO/WHO (2006) Probiotics in food. Health and nutritional properties and guidelines for evaluation. Fao Food and Nutrition Paper 85. Reports of Joint FAO/WHO expert consultations.

Fontana L, Bermudez-Brito M, Plaza-Diaz J, Muñoz-Quezada S, Gil A (2013) Sources, isolation, characterization and evaluation of probiotics. Brit J Nutrition 109, S35-S50.

Granum, P. E., T. Lund (1997) Bacillus cereus and its food poisoning toxins. FEMS Microbiol. Lett. 157:223–228.

Green, D. H., P. R. Wakeley, A. Page, A. Barnes, L. Baccigalupi, E. Ricca, S. M. Cutting (1999) Characterization of two Bacillus probiotics. Appl Environ Microbiol 65, 4288–4291.

Hoa, N. T., L. Baccigalupi, A. Huxham, A. Smertenko, P. H. Van, S. Ammendola, E. Ricca, A. S. Cutting (2000) Characterization of Bacillus species used for oral bacteriotherapy and bacterioprophylaxis of gastrointestinal disorders. Appl Environ Microbiol 66, 5241–5247.

Hong HA, Dic LH, Cutting SM (2005) The use of bacterial spore formers as probiotics. FEMS Microbiol Rev 29, 813-835.

Hong HA, Khaneja R, Tam NMK, Cazzato A, Tan S, Urdaci M, Brisson A, Gasbarrini A, Barnes I, Cutting SM (2009) Bacillus subtilis isolated from the human gastrointestinal tract. Res Microbiol 160, 134-143.

Lee S, Lee J, Jin YI, Jeong JC, Hyuk YH, Lee Y, Jeong Y, Kim M (2017) Probiotic characteristics of Bacillus strains isolated from Korean traditional soy sauce. LWT – Food Sci Technol 79, 518-524.

Mazza P (1994) The use of Bacillus subtilis as an antidiarrhoeal microorganism. Boll Chim. Farm. 133, 3-18.

Nimrat S, Suksawat S, Boonthai T, Vuthiphandchai V (2012) Potential Bacillus probiotics enhance bacterial numbers, water quality and growth during early development of white shrimp (Litopenaeus vannamei). Veterinary Microbiol 159, 443-450.

Phromraksa P, Nagano H, Kanamaru Y, Izumi H, Yamada C, Khamboonruang C (2009) Characterization of Bacillus subtilis isolated from Asian fermented foods. Food Sci Technol Res 15, 659-666.

Sanders ME, Morelli L, Tompkins TA (2003) Sporeformers as human probiotics: Bacillus, Sporolactobacillus, and Brevibacillus. Compr Rev Food Sci Food Safety 2, 101-110

Vaseeharan, B., P. Ramasamy (2003) Control of pathogenic Vibrio spp. by Bacillus subtilis BT23, a possible probiotic treatment for black tiger shrimp Penaeus monodon. Lett Appl Microbiol 36, 83–87

World Gastroenterology Organisation Global Guidelines (2011) Probiotics and Prebiotics.

Xiao et al. (2015) A catalogue of the mouse gut metagenome. Nature Biotechnol 33, 1103-1108.

Fig 0 pinterest-com cool bacillus-subtilis-science-comics

 

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